Enteroviruses and type 1 diabetes: towards a better understanding of the relationship.

Environmental factors, especially viruses, are involved in the initiation or the acceleration of type 1 diabetes (T1D) pathogenesis. Epidemiological data strongly suggest that enteroviruses, such as coxsackievirus B4 (CV-B4), can be associated with T1D. It has been demonstrated that enterovirus infections were significantly more prevalent in at risk individuals, such as siblings of diabetic patients, when they developed anti-beta-cell autoantibodies or T1D, and in recently diagnosed diabetic patients, compared with control subjects. The isolation of CV-B4 from the pancreas of diabetic patients strengthened the hypothesis of a relationship between the virus and the disease. Studies performed in vitro and in vivo in animal models helped to discover mechanisms of the infection of pancreas and other tissues, potentially able to play a role in the pathogenesis of T1D. Interestingly, it cannot be excluded that enteroviruses behave as half-devil half-angel since experimental studies suggest that, in certain conditions, these agents would be able to protect individuals against the disease. All of the plausible mechanisms by which enterovirus may be related to T1D will be reviewed here.

Pathogenesis of type 1 diabetes mellitus: interplay between enterovirus and host.

Enteroviruses are believed to contribute to the pathogenesis of type 1 diabetes mellitus (T1DM). In this Review, the interplay between infection with enteroviruses, the immune system and host genes is discussed. Data from retrospective and prospective epidemiological studies strongly suggest the involvement of enteroviruses, such as coxsackievirus B, in the development of T1DM. Enteroviral RNA and/or proteins can be detected in tissues of patients with T1DM. Isolation of coxsackievirus B4 from the pancreas of patients with T1DM or the presence of enteroviral components in their islets strengthens the hypothesis of a relationship between the virus and the disease. Enteroviruses can play a part in the early phase of T1DM through the infection of beta cells and the activation of innate immunity and inflammation. In contrast with its antiviral role, virus-induced interferon alpha can be deleterious, acting as an initiator of the autoimmunity directed against beta cells. Enteroviruses, through persistent and/or successive infections, can interact with the adaptive immune system. Host genes, such as IFIH1, that influence susceptibility to T1DM are associated with antiviral activities. An increased activity of the IFIH1 protein may promote the development of T1DM. An improved knowledge of the pathogenic mechanisms of enterovirus infections should help to uncover preventive strategies for T1DM.

Mechanisms and results of the antibody-dependent enhancement of viral infections and role in the pathogenesis of coxsackievirus B-induced diseases.

The mechanisms of the antibody-dependent enhancement (ADE) of viral infection are presented, particularly within the Picornaviridae family. The ADE of infection has been described in both human and animal models, worsens viral infections and compromises vaccine safety. The ADE of coxsackievirus B infection can also be implied in the pathogenesis of diseases like chronic dilated cardiomyopathy or insulin-dependent type 1 diabetes.

A part of the VP4 capsid protein exhibited by coxsackievirus B4 E2 is the target of antibodies contained in plasma from patients with type 1 diabetes.

The capsid protein VP4 was identified previously as the target of antibodies contained in plasma enhancing the coxscakievirus B4 (CV-B4) E2-induced production of IFN-alpha by peripheral blood mononuclear cells (PBMCs). The sequence of VP4 recognized by these antibodies was investigated. This sequence was identified as amino acids 11 to 30 by using synthetic overlapping peptides spanning VP4(CV-B4 E2) in competition experiments for antibodies enhancing the CV(B4 E2) induced production of IFN-alpha by PBMCs. This amino acid sequence was the major target of anti-VP4 antibodies according to enzyme-linked immunosorbent assays (ELISA). There was a positive correlation between the levels of anti-VP4 and anti-VP4(11-30) peptide antibodies detected by ELISA. The levels and the prevalences of these antibodies were significantly higher in patients with type 1 diabetes than in healthy controls. The proportions and the levels of those antibodies in patients were independent of HLA-DR alleles, age, or presence of ketosis in blood and were not associated with newly or previously diagnosed disease. The VP4(CV-B4 E2) amino acid sequence was submitted to the Swiss-model in project mode to visualize the possible shape of the sequence of VP4 corresponding to amino acids 11-30 which appeared to be constituted principally by an non-structured loop. In conclusion, the sequence of VP4 corresponding to amino acids 11-30, or a part of it plays a role in the plasma-dependent enhancement of CV-B4 E2-induced production of IFN-alpha by PBMCs, suggesting that at 37 degrees C the virus exhibits that region of VP4 to antibodies.

Role of the capsid protein VP4 in the plasma-dependent enhancement of the Coxsackievirus B4E2-infection of human peripheral blood cells.

It has been previously shown that antibodies contained in human plasma directed towards the Coxsackievirus B4 (CVB4)E2 capsid protein VP4 can enhance the CVB4E2-induced production of IFN-alpha by peripheral blood mononuclear cells (PBMC). The aim of this study was to produce a VP4 fusion protein to investigate the role of the internal capsid protein VP4 and anti-VP4 antibodies in the plasma-dependent enhancement of CVB4E2 infection of PBMC. A fusion protein MBPVP4 containing the VP4 insert of CVB4E2 and a control fusion protein MBP-beta-gal-alpha, were produced in Escherichia coli K12 TB1. The CVB4E2 infection of PBMC was quantified by using a real time PCR method amplifying CVB4E2-negative strand RNA. IFN-alpha concentrations in culture supernatants were assayed by DELFIA. MBPVP4 but not MBP-beta-gal-alpha, preincubated with plasma inhibited the plasma-dependent enhancement of CVB4E2-induced production of IFN-alpha by PBMC. Human plasma samples, antibodies contained in plasma eluted from MBPVP4-coated plates, but not from MBP-beta-gal-alpha-coated plates, incubated with CVB4E2 enhanced the infection of PBMC and the production of IFN-alpha by infected cells. Together our results show that VP4 and anti-VP4 antibodies play a role in the plasma-dependent enhancement of CVB4E2 infection of PBMC.

Viral protein VP4 is a target of human antibodies enhancing coxsackievirus B4- and B3-induced synthesis of alpha interferon.

Coxsackievirus B4 (CVB4)-induced production of alpha interferon (IFN-alpha) by peripheral blood mononuclear cells (PBMC) is enhanced in vitro by nonneutralizing anti-CVB4 antibodies from healthy subjects and, to a higher extent, from patients with insulin-dependent diabetes mellitus. In this study, we focused on identification of the viral target of these antibodies in CVB systems. High levels of IFN-alpha were obtained in supernatants of PBMC incubated with CVB4E2 or CVB3 and plasma from healthy subjects and, to a higher extent, from patients. The VP4 capsid proteins dissociated by heating at 56 degrees C from CVB4E2 (VP4(CVB4)) and CVB3 (VP4(CVB3)) but not H antigen preincubated with plasma from healthy subjects or patients inhibited the plasma-dependent enhancement of CVB4E2- and CVB3-induced IFN-alpha synthesis. There was no cross-reaction between VP4(CVB4) and VP4(CVB3) in the inhibiting effect. IFN-alpha levels in culture supernatants showed dose-dependent correlation with anti-VP4 antibodies eluted from plasma specimens using VP4-coated plates. There were higher index values for anti-VP4 antibodies detected by enzyme-linked immunosorbent assay (ELISA) and higher proportions of positive detection in 40 patients than in 40 healthy subjects (80% versus 15% for anti-VP4(CVB4)). There was no relationship between the levels of anti-CVB neutralizing antibodies and the detection of anti-VP4 antibodies by ELISA. The CVB plasma-induced IFN-alpha levels obtained in PBMC cultures in the anti-VP4 antibody-positive groups were significantly higher than those obtained in the anti-VP4 antibody-negative groups regardless of the titers of anti-CVB neutralizing antibodies. These results show that VP4 is the target of antibodies involved in the plasma-dependent enhancement of CVB4E2- and CVB3-induced IFN-alpha synthesis by PBMC.